Method for defining a gap height within an image sensor package

ABSTRACT

According to an aspect, an image sensor package includes a substrate, an image sensor die coupled to the substrate, a light transmitting member, and a plurality of pillar members disposed between and contacting the image sensor die and the light transmitting member. A height of the plurality of pillar members defines a gap height between an active region of the image sensor die and the light transmitting member. The image sensor package including a bonding material that couples the light transmitting member to the image sensor. The bonding material contacts a side of a pillar member, of the plurality of pillar members, that extends between a first end contacting the light transmitting member and a second end contacting the image sensor die.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of U.S. patentapplication Ser. No. 16/948,792, filed Oct. 1, 2020, which claimspriority to and the benefit of U.S. Provisional Application No.62/705,769, filed Jul. 15, 2020, these applications are incorporated byreference herein in their entireties.

TECHNICAL FIELD

This description relates to a method for controlling a gap height withinan image sensor package.

BACKGROUND

Within an image sensor package, an image sensor die is coupled to aglass substrate with a bonding material. The thickness of the bondingmaterial may define the height of an air gap between the image sensordie and the glass substrate. According to some conventionalmanufacturing approaches, controlling the gap height in an accuratemanner is relatively difficult. For example, the bonding material isdispensed on the image sensor die, and then the glass substrate may bedropped on the bonding material, thereby making the gap height dependupon the resin volume and viscosity of the bonding material. This maycause variations in the gap height during production of image sensorpackages.

SUMMARY

According to an aspect, a method for fabricating an image sensor packageto define a gap height includes coupling an image sensor die to asubstrate, forming a plurality of pillar members on the image sensordie, dispensing a bonding material on the image sensor die, contacting atransparent member with the bonding material such that a height of thepillar members defines a gap height between an active region of theimage sensor die and the transparent member, and curing the bondingmaterial to couple the transparent member to the image sensor die.

According to some aspects, the method may include one or more of thefollowing features (or any combination thereof). The forming theplurality of pillar members on the image sensor die may includedispensing a liquid epoxy resin on the image sensor die and curing theliquid epoxy resin to form the plurality of pillar members. The liquidepoxy resin is cured using ultraviolet (UV) light. The forming theplurality of pillar members on the image sensor die may include creatingconductive members. The bonding material is dispensed on the pillarmembers such that the bonding material encompasses the plurality ofpillar members. The bonding material is dispensed on a perimeter portionof a mount area of the image sensor die. Each of the plurality of pillarmembers is formed on a separate corner portion of the mount area of theimage sensor die. The bonding material includes a liquid epoxy resin,where the liquid epoxy resin is cured to form a solid bonding material.The method may include coupling bond wires to the image sensor die andto the substrate before the plurality of pillar members are formed onthe image sensor die. The method may include dispensing a moldingmaterial on the substrate after the bonding material is cured.

According to an aspect, a method for fabricating an image sensor packageto define a gap height includes coupling an image sensor die to asubstrate, coupling bond wires to the image sensor die and to thesubstrate, forming a plurality of pillar members on a mount area of theimage sensor die, the mount area being disposed outside an active regionof the image sensor die, dispensing a bonding material on the mount areaof the image sensor die, contacting a transparent member with thebonding material such that a height of the plurality of pillar membersdefines a gap height between the active region of the image sensor dieand the transparent member, and curing the bonding material to couplethe transparent member to the image sensor die.

According to some aspects, the method may include one or more of theabove/below features (or any combination thereof). The forming theplurality of pillar members on the mount area of the image sensor diemay include dispensing a liquid epoxy resin on corner portions of themount area of the image sensor die and curing the liquid epoxy resin toform the plurality of pillar members. The forming the plurality ofpillar members on the mount area of the image sensor die may includecreating a conductive member on a separate corner portion of the mountarea of the image sensor die. A pillar member of the plurality of pillarmembers may include a first linear portion and a second linear portion,where the second linear portion is disposed at a non-zero angle withrespect to the first linear portion. The bonding material is dispensedon a perimeter portion of the mount area of the image sensor die, wherethe bonding material covers the plurality of pillar members.

According to an aspect, a method for fabricating an image sensor packageto define a gap height includes dispensing a bonding material on a mountarea of an image sensor die, the image sensor die being coupled to asubstrate, coupling a transparent member to a bond head, moving the bondhead to a programmable position to place the transparent member incontact with the bonding material, where the programmable positiondefines a gap height between an active region of the image sensor dieand the transparent member, curing the bonding material to couple thetransparent member to the image sensor die while the bond head iscoupled to the transparent member, and releasing the bond head from thetransparent member.

According to some aspects, the method may include one or more of thefollowing features (or any combination thereof). The method may includereprogramming, using a controller operably coupled to the bond head, theposition to increase the gap height between the active region of theimage sensor die and the transparent member. The bonding materialincludes a liquid epoxy resin that is cured to form a solid bondingmaterial, where the epoxy resin has a viscosity greater than a thresholdlevel. The coupling the transparent member to the bond head includesactivating vacuum suction on the bond head. The releasing the bond headfrom the transparent member includes deactivating vacuum suction on thebond head. The method may include dispensing a molding material on thesubstrate after the bond head is released from the transparent member.

The details of one or more implementations are set forth in theaccompanying drawings and the description below. Other features will beapparent from the description and drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A through 1C illustrate an image sensor package configured to befabricated in a manner that permits a gap height to be controlledaccording to an aspect.

FIGS. 2A through 2C illustrate an image sensor package according to anaspect.

FIGS. 3A through 3N illustrate a flowchart for fabricating an imagesensor package.

FIG. 4 illustrates an image sensor package configured to be fabricatedin a manner that permits a gap height to be controlled according to anaspect.

FIG. 5 illustrates an image sensor package according to another aspect.

FIGS. 6A through 6F illustrate a flowchart for fabricating an imagesensor package.

FIG. 7 illustrates a flowchart for fabricating an image sensor packageaccording to an aspect.

FIG. 8 illustrates a flowchart for fabricating an image sensor packageaccording to another aspect.

FIG. 9 illustrates a flowchart for fabricating an image sensor packageaccording to another aspect.

DETAILED DESCRIPTION

The present disclosure relates to a method of defining (e.g.,controlling) a gap height between an image sensor die and a transparentmember. For example, during production of an image sensor package, animage sensor die is coupled to a substrate, and pillar members areformed on a mount area of the image sensor die. The mount area may bethe space in which bonding material is dispensed in order to couple atransparent member (e.g., a glass substrate) to the image sensor die. Insome examples, a pillar member is formed on a separate corner portion ofthe mount area. In some examples, the pillar members are formed bydispensing a liquid epoxy resin on the corner portions of the mount areaof the image sensor die and curing the liquid epoxy resin (e.g., usingultraviolet (UV) light or heat/baking) to form the pillar members. Insome examples, the pillar members include conductive members (e.g.,metal bumps) formed by a lithography and plating process.

As further discussed below, the height of the pillar members may definethe gap height between the active region of the image sensor die and thetransparent member. After the pillar members are formed, a bondingmaterial (e.g., a liquid epoxy resin) is dispensed on the mount area ofthe image sensor die (thereby covering the pillar members). Then, thetransparent member is placed on the bonding material, where the bondingmaterial is cured to couple the transparent member to the image sensordie. In some examples, the bonding material is dispensed around aperimeter area of the mount area of the image sensor die.

The height of the pillar members may control (or define) the gap heightbetween the active region of the image sensor die and the transparentmember. When the transparent member is placed (e.g., dropped) on thebonding material (which is not yet cured and may be still liquid), therigid structure of the pillar members contact the transparent materialand hold the transparent material a distance away from the image sensordie, thereby providing a relatively precise gap height. In this manner,the gap height is not dependent upon the resin volume and viscosity ofthe bonding material, but rather the height of the pillar members.

In some examples, a bonding material (e.g., a liquid epoxy resin) isdispensed on the mount area of the image sensor die. Then, a transparentmember is coupled to a bond head. The bond head may be moved to placethe transparent member in contact with the bonding material. The bondhead may be a movable component that uses vacuum suction to couple thetransparent member and move the transparent member to a programmableposition. The programmable position may define the gap height betweenthe active region of the image sensor die and the transparent member.Then, the bonding material is cured to couple the transparent member tothe image sensor while the bond head is coupled to the transparentmember. Then, the bond head is released from the transparent member. Insome examples, the position is reprogrammed using a controller operablecoupled to the bond head in order to increase the gap height between theactive region of the image sensor die and the transparent member. Inthis manner, the transparent member is not dropped on the bondingmaterial, but rather placed in the desired position away from the imagesensor die in order to define the gap height. Using these techniques,the gap height is not dependent upon the resin volume and viscosity ofthe bonding material, but rather the position of the bond head, therebymaking the gap height more precise.

FIGS. 1A through 1C illustrate an image sensor package 100 configured tobe fabricated in a manner that permits a gap height 105 to be controlledaccording to an aspect. In some examples, the image sensor package 100includes a complementary metal-oxide-semiconductor (CMOS) image sensor(CIS) package. The image sensor package 100 includes a substrate 102, animage sensor die 104 coupled to the substrate 102, and a transparentmember 106 coupled to the image sensor die 104 such that an air gap 103exists between the transparent member 106 and an active region 108 ofthe image sensor die 104.

The substrate 102 includes a first surface 112 and a second surface 114.The first surface 112 of the substrate 102 is disposed in a plane A4. Insome examples, the second surface 114 is disposed in parallel with thefirst surface 112. A direction A1 is aligned perpendicular to the planeA4, and a direction A2 is perpendicular to the direction A1. A directionA3 is aligned parallel to the plane A4 and is orthogonal to directionsA1 and A2. As shown in FIG. 1A, the direction A3 is depicted into thepage (shown as a dot). FIG. 1A depicts a side view of the image sensorpackage 100. FIGS. 1B and 1C depict a top view of the image sensor die104. For example, FIG. 1B illustrates the image sensor die 104 withpillar members 125 disposed at corner portions of a mount area 123before a bonding material 124 is applied. FIG. 1C illustrates the imagesensor die 104 with the bonding material 124 applied to the mount area123, where the bonding material 124 covers the pillar members 125. SinceFIGS. 1B and 1C depict a different orientation than FIG. 1A, thedirection A1 is depicted into the page (shown as a dot). The directionsA1, A2, and A3, and plane A4, are used throughout several of the variousviews of the implementations described throughout the figures forsimplicity. The image sensor die includes a first surface 116 and asecond surface 118. The first surface 116 defines an active region 108of the image sensor die 104. The transparent member 106 includes a firstsurface 126 and a second surface 128.

The gap height 105 is the height of the air gap 103. The air gap 103 maybe empty space (e.g., devoid of components). The gap height 105 is thedistance between the active region 108 of the image sensor die 104 andthe transparent member 106 in the direction A1. In some examples, thegap height 105 is the distance between the second surface 128 of thetransparent member 106 and the first surface 116 of the image sensor die104 in the direction A1. According to the techniques described herein,the gap height 105 can be defined in a relatively precise manner inorder to meet a desired designed specification. Also, in some examples,the gap height 105 can be increased to provide a relatively larger airgap 103, which may be beneficial for some applications.

The transparent member 106 is coupled to the image sensor die 104 via abonding material 124 and pillar members 125. The height of the pillarmembers 125 may define the gap height 105 and may assist with ensuring arelatively precise gap height 105. For example, each pillar member 125includes a first end 141 and a second end 143. The distance between thefirst end 141 and the second end 143 in the direction A1 may define theheight of a respective pillar member 125. The first end 141 may contact(e.g., directly contact) the first surface 116 of the image sensor die104 (at a region outside of the active region 108). The second end 143may contact (e.g., directly contact) the second surface 128 of thetransparent member 106. In some examples, each pillar member 125 hassubstantially the same height. In some examples, one or more of thepillar members 125 has a height that is different from one or more otherpillar members 125.

Before the bonding material 124 is dispensed, the pillar members 125 areformed on the image sensor die 104. Then, the bonding material 124 isdispensed on the image sensor die 104 (and the pillar members 125). Insome examples, the bonding material 124 includes a liquid epoxy resinthat is deposited on portions of the image sensor die 104 and the pillarmembers 125. The pillar members 125 provide a relatively rigid structurethat operates as a landing pad to receive the transparent member 106when the transparent member 106 is placed (e.g., dropped) on the bondingmaterial 124. For example, the transparent member 106 is placed incontact with the bonding material 124, where the relatively rigidstructure of the pillar members 125 holds the transparent member 106 ata fixed location (defined by the height of the pillar members 125) whilethe bonding material 124 (e.g., the liquid epoxy resin) is cured inorder to couple the image sensor die 104 to the transparent member 106.

If the image sensor package 100 did not include the pillar members 125,and, when the transparent member 106 is dropped on top of the imagesensor die 104, the transparent member 106 may sink into the relativelysoft bonding material 124, thereby causing a relatively imprecise gapheight 105. However, according to the techniques described herein, whenthe transparent member 106 is placed (e.g. dropped) on top of the imagesensor die 104, the relatively rigid structure of the pillar members 125causes the transparent member 106 to be positioned away from the activeregion 108 of the image sensor die 104 by the height of the pillarmembers 125, which corresponds to the gap height 105. This leads to amore precise gap height 105.

As shown in FIG. 1B, the pillar members 125 are formed on a mount area123 of the first surface 116 of the image sensor die 104. The mount area123 may be outside of the active region 108. In some examples, theactive region 108 has a rectangular shape. In some examples, the activeregion 108 has a square shape. The mount area 123 is the space adjacentto a perimeter 109 of the active region 108. The area inside of theperimeter 109 of the active region 108 corresponds to or defines pixelelements configured to convert electromagnetic radiation (e.g., light)to electrical signals. In some examples, the mount area 123 is the spaceon the first surface 116 between the perimeter 109 of the active region108 and contact terminals 117. The contact terminals 117 may be theexposed conductive pads that are configured to be coupled to anothercomponent (e.g., the substrate 102). In some examples, the contactterminals 117 are aligned in a row proximate to each edge of the imagesensor die 104. Since the image sensor die 104 includes four edges,there are four aligned rows of contact terminals 117. Bond wires 122 maybe connected to one or more of the contact terminals 117 and thesubstrate 102.

Each pillar member 125 is a separate structure that extends from themount area 123 on the first surface 116 of the image sensor die 104 inthe direction A1. In some examples, the pillar members 125 are spacedapart from each other on the mount area 123. In some examples, aparticular pillar member 125 is disposed on a separate corner portion ofthe mount area 123. In some examples, each pillar member 125 is disposedon a portion of the mount area 123 at a location proximate to a separatecorner of the active region 108. In some examples, each pillar member125 has an L-shape.

In some examples, each pillar member 125 includes a first linear portion131 and a second linear portion 133. The second linear portion 133extends from the first linear portion 131. The second linear portion 133is disposed at a non-zero angle with respect to the first linear portion131. In some examples, the second linear portion 133 is perpendicular tothe first linear portion 131. The first linear portion 131 has a lengththat extends in the direction A2, a width that extends in the directionA3, and a height that extends in the direction A1. The second linearportion 133 has a length that extends in the direction A3, a width thatextends in the direction A2, and a height that extends in the directionA1.

In some examples, each pillar member 125 has the same shape with respectto each other. In some examples, one or more pillar members 125 has ashape that is different from one or more other pillar members 125. Insome examples, the pillar members 125 may encompass other shapes (e.g.,besides the L-shape) such as a single linear shape, a shape having oneor more curved or bent portions and/or one or more linear portions, aT-shape, or generally any type of shape that extends in the directionA1.

In some examples, the pillar members 125 are formed with a bondingmaterial (e.g., adhesive, epoxy resin, etc.). In some examples, thepillar members 125 are formed by dispensing a liquid epoxy resin on theimage sensor die 104, and then curing the liquid epoxy resin to form thepillar members 125. In some examples, the liquid epoxy resin is curedusing UV light. In some examples, the pillar members 125 are formed witha conductive material (e.g., Au, Cu, Ni, Al, etc.). In some examples,the pillar members 125 are formed by creating conductive members (e.g.,metal bumps) using a lithography and plating process.

As shown in FIG. 1C, after the pillar members 125 are formed, thebonding material 124 is dispensed on the mount area 123 of the imagesensor die 104, thereby covering the pillar members 125. In someexamples, the bonding material 124 includes a liquid epoxy resin. Insome examples, the amount of liquid epoxy resin used for the bondingmaterial 124 is greater than the amount of liquid epoxy resin used tocreate the pillar members 125. In some examples, the liquid epoxy resinused for the bonding material 124 is applied to a greater surface areathan the liquid epoxy resin used to create the pillar members 125.

After the bonding material 124 (e.g., the liquid epoxy resin) isdispensed, the transparent member 106 is placed in contact with thebonding material 124 (e.g., the liquid epoxy resin) and the pillarmembers 125. For example, at this point, since the bonding material 124is relatively soft (e.g., not cured), the transparent member 106 maysink into the bonding material 124 until the second surface 128 of thetransparent member 106 contacts the pillar members 125. Then, thebonding material 124 (e.g., the liquid epoxy resin) is cured to couplethe transparent member 106 to the image sensor die 104 while the pillarmembers 125 hold the transparent member 106 at the desired distance awayfrom the active region 108.

In some examples, the bonding material 124 is disposed on the mount area123 around the active region 108. In some examples, the bonding material124 is disposed around a perimeter portion of the mount area 123(thereby forming a closed loop). In some examples, the bonding material124 defines an inner perimeter 111 and an outer perimeter 113. Thepillar members 125 are disposed at a location between the innerperimeter 111 and the outer perimeter 113. In some examples, the bondingmaterial 124 covers the pillar members 125. In some examples, a portionof the bonding material 124 contacts the second end 143 of the pillarmembers 125. The inner perimeter 111 may define an inner edge of thebonding material 124. The outer perimeter 113 may define an outer edgeof the bonding material 124. The bonding material 124 extends betweenthe inner perimeter 111 and the outer perimeter 113. The outer perimeter113 may have a length that is larger than the inner perimeter 111. Theinner perimeter 111 may form a closed loop around the active region 108.The inner perimeter 111 may be disposed a distance away from theperimeter 109 of the active region 108 in the directions A2 and A3. Forexample, an empty space may exist between the perimeter 109 and theinner perimeter 111. The outer perimeter 113 may form a closed looparound the active region 108. The outer perimeter 113 is disposed adistance away from the contact terminals 117. For example, an emptyspace may exist between the contact terminals 117 and the outerperimeter 113.

The substrate 102 includes a printed circuit board (PCB) substrate. Insome examples, the substrate 102 includes a dielectric material. In someexamples, the substrate 102 includes a single layer of PCB basematerial. In some examples, the substrate 102 includes multiple layersof PCB base material. In some examples, the substrate 102 includes oneor more conductive layer portions (e.g., electrical traces) disposed onthe first surface 112 of the substrate 102, and/or one or moreconductive layer portions (e.g., electrical traces) disposed on thesecond surface 114 of the substrate 102. In some examples, theelectrical traces may be configured to and/or used to transmit signalsto and/or from devices (e.g., electronic devices included in asemiconductor region (e.g., epitaxial layer and/or semiconductorsubstrate)) connected to the electrical traces. In some examples, theelectrical traces can include conductive traces (e.g., metallic traces)such as copper traces, aluminum traces, and/or so forth.

The image sensor die 104 may include a complementary metal-oxidesemiconductor (CMOS) image sensor. In some examples, the first surface116 (and/or the second surface 118) is parallel to the first surface 112(and/or the second surface 114). The image sensor die 104 defines theactive region 108 on the first surface 116 of the image sensor die 104.The active region 108 may have or correspond with, an array of pixelelements configured to convert electromagnetic radiation (e.g., light)to electrical signals.

The image sensor die 104 is coupled to the substrate 102. For example,the second surface 118 of the image sensor die 104 may be coupled to thefirst surface 112 of the substrate 102 using one or more bondingmaterials (e.g., an adhesive layer, die attach film, polymer-basedmaterial, an epoxy resin, etc.) in order to physically couple the imagesensor die 104 to the substrate 102. In some examples, the bond wires122 are connected to the image sensor die 104 and the substrate 102 inorder to communicatively couple the image sensor die 104 to thesubstrate 102. The bond wires 122 may include conductive (e.g., metal)wires such as aluminum, copper, or gold, or any combination thereof, forexample. In some examples, the image sensor die 104 is coupled to thesubstrate 102 in a flip-chip configuration. In some examples, the imagesensor die 104 is coupled to the substrate 102 by surface mounttechnology (SMT) (e.g., interconnection by solder joint). In someexamples, the image sensor die 104 is coupled to the first surface 112of the substrate 102 using one or more bump members (e.g., copperpillars with solder, gold plated bumps, solder bumps, and/or gold studbumps, etc.). In some examples, an under-fill material is disposedwithin the gap between the image sensor die 104 and the substrate 102,where the under-fill material encapsulates the bump members.

The transparent member 106 is coupled to the image sensor die 104 suchthat the transparent member 106 is positioned over (and spaced apartfrom) the active region 108 on the first surface 116 of the image sensordie 104 in the direction A1. In some examples, the first surface 126(and/or the second surface 128) is parallel to the first surface 116(and/or the second surface 118). The transparent member 106 includes anoptically transparent material that allows electromagnetic radiation(e.g., light (e.g., visible light)) to pass through (e.g., pass throughthe entirety of the material). In some examples, the transparent member106 includes an optically transparent material that allows thetransmission of light waves without being scattered (or being scatteredto a relatively small or negligible degree). In some examples, thetransparent member 106 includes a cover. In some examples, thetransparent member 106 includes a lid. In some examples, the transparentmember 106 includes one or more organic materials and/or one or moreinorganic materials. In some examples, the transparent member 106includes a glass material. In some examples, the transparent member 106is a glass substrate. In some examples, the transparent member 106includes one or more layers of transparent material.

The image sensor package 100 includes an encapsulation material 130configured to encapsulate one or more components of the image sensorpackage 100. In some examples, the encapsulation material 130 is formedfrom a liquid encapsulation. In some examples, the encapsulationmaterial 130 includes a molding material. The encapsulation material 130includes one or more types of material (e.g., in a molding compound ifincluding multiple types of materials) such as a metal, a plastic, aresin, an epoxy, a phenolic hardener, a silica material, a pigment, aglass, a ceramic casing, and/or so forth. The encapsulation material 130may encapsulate the bond wires 122. The encapsulation material 130 maybe disposed on the first surface 112 of the substrate 102 at locationsadjacent to the image sensor die 104. The encapsulation material 130 mayextend along an edge of the image sensor die 104, the bonding material124, and/or an edge of the transparent member 106.

FIGS. 2A through 2C illustrate an image sensor package 200 according toan aspect. In some examples, the image sensor package 200 includes acomplementary metal-oxide-semiconductor (CMOS) image sensor (CIS)package. The image sensor package 200 may include any of the featuresdescribed with respect to the image sensor package 100 of FIGS. 1Athrough 1C. The image sensor package 200 includes a substrate 202, animage sensor die 204 coupled to the substrate 202, and a transparentmember 206 coupled to the image sensor die 204 such that an air gap 203(e.g., empty space) exists between an active region 208 of the imagesensor die 204 and the transparent member 206.

The substrate 202 includes a first surface 212 and a second surface 214.The first surface 212 of the substrate 202 is disposed in a plane A4. Insome examples, the second surface 214 is disposed in parallel with thefirst surface 212. A direction A1 is aligned perpendicular to the planeA4, and a direction A2 is perpendicular to the direction A1. A directionA3 is aligned parallel to the plane A4 and is orthogonal to directionsA1 and A2. As shown in FIG. 2A, the direction A3 is depicted into thepage (shown as a dot). FIG. 2A depicts a side view of the image sensorpackage 200. FIGS. 2B and 2C depict a top view of the image sensor die204. For example, FIG. 2B illustrates the image sensor die 204 withpillar members 225 disposed at corner portions of a mount area 223before a bonding material 224 is applied. FIG. 2C illustrates the imagesensor die 204 with the bonding material 224 applied to the mount area223, where the bonding material 224 covers the pillar members 225.

Since FIGS. 2B and 2C depict a different orientation than FIG. 2A, thedirection A1 is depicted into the page (shown as a dot). The directionsA1, A2, and A3, and plane A4, are used throughout several of the variousviews of the implementations described throughout the figures forsimplicity. The image sensor die includes a first surface 216 and asecond surface 218. The first surface 216 defines an active region 208of the image sensor die 204. The transparent member 206 includes a firstsurface 226 and a second surface 228.

The gap height 205 is the height of the air gap 203. The air gap 203 maybe empty space (e.g., devoid of components). The gap height 205 is thedistance between the active region 208 of the image sensor die 204 andthe transparent member 206 in the direction A1. In some examples, thegap height 205 is the distance between the second surface 228 of thetransparent member 206 and the first surface 216 of the image sensor die204 in the direction A1. According to the techniques described herein,the gap height 205 can be defined in a relatively precise manner inorder to meet a desired designed specification. Also, in some examples,the gap height 205 can be increased to provide a relatively larger airgap 203, which may be beneficial for some applications.

The transparent member 206 is coupled to the image sensor die 204 via abonding material 224 and pillar members 225. The height of the pillarmembers 225 may define the gap height 205 and may assist with ensuring arelatively precise gap height 205. For example, each pillar member 225includes a first end 241 and a second end 243. The distance between thefirst end 241 and the second end 243 in the direction A1 may define theheight of a respective pillar member 225. The first end 241 may contact(e.g., directly contact) the first surface 216 of the image sensor die204 (at a region outside of the active region 208). The second end 243may contact (e.g., directly contact) the second surface 228 of thetransparent member 206. In some examples, each pillar member 225 hassubstantially the same height. In some examples, one or more of thepillar members 225 has a height that is different from one or more otherpillar members 225.

Before the bonding material 224 is dispensed, the pillar members 225 areformed on the image sensor die 204. Then, the bonding material 224 isdispensed on the image sensor die 204 and the pillar members 225. Insome examples, the bonding material 224 includes a liquid epoxy resinthat is deposited on portions of the image sensor die 204 and the pillarmembers 225. The pillar members 225 provide a relatively rigid structurethat operates as a landing pad to receive the transparent member 206when the transparent member 206 is placed (e.g., dropped) on the bondingmaterial 224. For example, the transparent member 206 is placed incontact with the bonding material 224, where the relatively rigidstructure of the pillar members 225 holds the transparent member 206 ata fixed location (defined by the height of the pillar members 225) whilethe bonding material 224 (e.g., the liquid epoxy resin) is cured inorder to couple the image sensor die 204 to the transparent member 206.

If the image sensor package 200 did not include the pillar members 225,and, when the transparent member 206 is dropped on top of the imagesensor die 204, the transparent member 206 may sink into the relativelysoft bonding material 224, thereby causing a relatively unprecise gapheight 205. However, according to the techniques described herein, whenthe transparent member 206 is placed (e.g. dropped) on top of the imagesensor die 204, the relatively rigid structure of the pillar members 225causes the transparent member 206 to be positioned away from the activeregion 208 of the image sensor die 204 by the height of the pillarmembers 225, which corresponds to the gap height 205. This leads to amore precise gap height 205.

As shown in FIG. 2B, the pillar members 225 are formed on a mount area223 of the first surface 216 of the image sensor die 204. The mount area223 may be outside of the active region 208. In some examples, theactive region 208 has a rectangular shape. In some examples, the activeregion 208 has a square shape. In some examples, the mount area 223 isthe space adjacent to a perimeter 209 of the active region 208. The areainside of the perimeter 209 of the active region 208 corresponds to ordefines pixel elements configured to convert electromagnetic radiation(e.g., light) to electrical signals. In some examples, the mount area223 is the space on the first surface 216 between the perimeter 209 ofthe active region 208 and contact terminals 217. The contact terminals217 may be the exposed conductive pads that are configured to be coupledto another component (e.g., the substrate 202). In some examples, thecontact terminals 217 are aligned in a row proximate to each edge of theimage sensor die 204. Since the image sensor die 204 includes fouredges, there are four aligned rows of contact terminals 217. Bond wires222 may be connected to one or more of the contact terminals 217 and thesubstrate 202.

Each pillar member 225 is a separate structure that extends from themount area 223 on the first surface 216 of the image sensor die 204 inthe direction A1. In some examples, the pillar members 225 are spacedapart from each other on the mount area 223. In some examples, aparticular pillar member 225 is disposed on a separate corner portion ofthe mount area 223. In some examples, each pillar member 225 is disposedon a portion of the mount area 223 at a location proximate to a separatecorner of the active region 208. In some examples, each pillar member225 has an L-shape.

In some examples, each pillar member 225 includes a first linear portion231 and a second linear portion 233. The second linear portion 233extends from the first linear portion 231. The second linear portion 233is disposed at a non-zero angle with respect to the first linear portion231. In some examples, the second linear portion 233 is perpendicular tothe first linear portion 231. The first linear portion 231 has a lengththat extends in the direction A2, a width that extends in the directionA3, and a height that extends in the direction A1. The second linearportion 233 has a length that extends in the direction A3, a width thatextends in the direction A2, and a height that extends in the directionA1.

In some examples, each pillar member 225 has the same shape with respectto each other. In some examples, one or more pillar members 225 has ashape that is different from one or more other pillar members 225. Insome examples, the pillar members 225 may encompass other shapes (e.g.,besides the L-shape) such as a single linear shape, a shape having oneor more curved or bent portions and/or one or more linear portions, aT-shape, or generally any type of shape that extends in the directionA1.

In some examples, the pillar members 225 are formed with a bondingmaterial (e.g., adhesive, epoxy resin, etc.). In some examples, thepillar members 225 are formed by dispensing a liquid epoxy resin on theimage sensor die 204, and then curing the liquid epoxy resin to form thepillar members 225. In some examples, the liquid epoxy resin is curedusing UV light. In some examples, the pillar members 225 are formed witha conductive material (e.g., Au, Cu, Ni, Al, etc.). In some examples,the pillar members 225 are formed by creating conductive members (e.g.,metal bumps) using a lithography and plating process.

As shown in FIG. 2C, after the pillar members 225 are formed, thebonding material 224 is dispensed on the mount area 223 of the imagesensor die 204, thereby covering the pillar members 225. In someexamples, the bonding material 224 includes a liquid epoxy resin. Insome examples, the amount of liquid epoxy resin used for the bondingmaterial 224 is greater than the amount of liquid epoxy resin used tocreate the pillar members 225. In some examples, the liquid epoxy resinused for the bonding material 224 is applied to a greater surface areathan the liquid epoxy resin used to create the pillar members 225.

After the bonding material 224 (e.g., the liquid epoxy resin) isdispensed, the transparent member 206 is placed in contact with thebonding material 224 (e.g., the liquid epoxy resin) and the pillarmembers 225. For example, at this point, since the bonding material 224is relatively soft (e.g., not cured), the transparent member 206 maysink into the bonding material 224 until the second surface 228 of thetransparent member 206 contacts the pillar members 225. Then, thebonding material 224 (e.g., the liquid epoxy resin) is cured to couplethe transparent member 206 to the image sensor die 204 while the pillarmembers 225 hold the transparent member 206 at the desired distance awayfrom the active region 208.

In some examples, the bonding material 224 is disposed on the mount area223 around the active region 208. In some examples, the bonding material224 is disposed around a perimeter portion of the mount area 223(thereby forming a closed loop). In some examples, the bonding material224 defines an inner perimeter 211 and an outer perimeter 213. Thepillar members 225 are disposed at a location between the innerperimeter 211 and the outer perimeter 213. In some examples, the bondingmaterial 224 covers the pillar members 225. In some examples, a portionof the bonding material 224 contacts the second end 243 of the pillarmembers 225. The inner perimeter 211 may define an inner edge of thebonding material 224. The outer perimeter 213 may define an outer edgeof the bonding material 224. The bonding material 224 extends betweenthe inner perimeter 211 and the outer perimeter 213. The outer perimeter213 may have a length that is larger than the inner perimeter 211. Theinner perimeter 211 may form a closed loop around the active region 208.The inner perimeter 211 may be disposed a distance away from theperimeter 209 of the active region 208 in the directions A2 and A3. Forexample, an empty space may exist between the perimeter 209 and theinner perimeter 211. The outer perimeter 213 may form a closed looparound the active region 208. The outer perimeter 213 is disposed adistance away from the contact terminals 217. For example, an emptyspace may exist between the contact terminals 217 and the outerperimeter 213.

The substrate 202 includes a printed circuit board (PCB) substrate. Insome examples, the substrate 202 includes a dielectric material. In someexamples, the substrate 202 includes a single layer of PCB basematerial. In some examples, the substrate 202 includes multiple layersof PCB base material. The substrate 202 includes a first surface 212 anda second surface 214 that is disposed opposite to the first surface 212.In some examples, the substrate 202 includes electrical traces 261. Theelectrical traces 261 may include one or more conductive layer portionsdisposed on the first surface 212 of the substrate 202, one or moreconductive layer portions (e.g., electrical traces) disposed on thesecond surface 214 of the substrate 202, and/or one or more conductivelayer portions embedded within the substrate 202.

The image sensor package 200 may include one or more conductivecomponents 220 coupled to the second surface 214 of the substrate 202.In some examples, the conductive components 220 are surface-mountpackaging elements. In some examples, the conductive components 220include solder balls. The conductive components 220 are components usedto connect to an external device (e.g., a ball grid array (BGA) device).However, the conductive components 220 may include other types ofsurface-mount packaging elements.

The image sensor die 204 may include a complementary metal-oxidesemiconductor (CMOS) image sensor. In some examples, the first surface216 (and/or the second surface 218) is parallel to the first surface 212(and/or the second surface 214). The image sensor die 204 defines theactive region 208 on the first surface 216 of the image sensor die 204.The active region 208 may have or correspond with, an array of pixelelements configured to convert electromagnetic radiation (e.g., light)to electrical signals.

The image sensor die 204 is coupled to the substrate 202. For example,the second surface 218 of the image sensor die 204 may be coupled tofirst surface 212 of the substrate 202 using one or more bondingmaterials (e.g., an adhesive layer, die attach film, polymer-basedmaterial, an epoxy resin, etc.) in order to physically couple the imagesensor die 204 to the substrate 202. In some examples, the bond wires222 are connected to the image sensor die 204 and the substrate 202 inorder to communicatively couple the image sensor die 204 to thesubstrate 202. The bond wires 222 may include conductive (e.g., metal)wires such as aluminum, copper, or gold, or any combination thereof, forexample. In some examples, the image sensor die 204 is coupled to thesubstrate 202 in a flip-chip configuration. In some examples, the imagesensor die 204 is coupled to the substrate 202 by surface mounttechnology (SMT) (e.g., interconnection by solder joint). In someexamples, the image sensor die 204 is coupled to the first surface 212of the substrate 202 using one or more bump members (e.g., copperpillars with solder, gold plated bumps, solder bumps, and/or gold studbumps, etc.). In some examples, an under-fill material is disposedwithin the gap between the image sensor die 204 and the substrate 202,where the under-fill material encapsulates the bump members.

The transparent member 206 is coupled to the image sensor die 204 suchthat the transparent member 206 is positioned over (and spaced apartfrom) the active region 208 on the first surface 216 of the image sensordie 204 in the direction A1. In some examples, the first surface 226(and/or the second surface 228) is parallel to the first surface 216(and/or the second surface 218). The transparent member 206 includes anoptically transparent material that allows electromagnetic radiation(e.g., light (e.g., visible light)) to pass through (e.g., pass throughthe entirety of the material). In some examples, the transparent member206 includes a glass material.

The image sensor package 200 includes an encapsulation material 230configured to encapsulate one or more components of the image sensorpackage 200. In some examples, the encapsulation material 230 is formedfrom a liquid encapsulation. In some examples, the encapsulationmaterial 230 includes a molding material. The encapsulation material 230may encapsulate the bond wires 222. The encapsulation material 230 maybe disposed on the first surface 212 of the substrate 202 at locationsadjacent to the image sensor die 204. The encapsulation material 230 mayextend along an edge of the image sensor die 204, an edge of the bondingmaterial 224, and/or an edge of the transparent member 206.

FIGS. 3A through 3M depict a flowchart depicting example fabricationoperations for manufacturing an image sensor package according to anaspect. Although the flowchart is described with reference to the imagesensor package 100 of FIGS. 1A through 1C, the flowchart may beapplicable to any of the sensor packaging packages discussed herein.Although the flowchart of FIGS. 3A through 3M illustrate operations insequential order, it will be appreciated that this is merely an example,and that additional or alternative operations may be included. Further,operations of FIGS. 3A through 3M and related operations may be executedin a different order than that shown, or in a parallel or overlappingfashion.

FIGS. 3A and 3B depict operation 302. In operation 302, a substrate 102is provided. The substrate 102 may include conductive traces 161. FIG.3A illustrates a side view of the substrate 102. FIG. 3B illustrates atop view of the substrate 102. FIGS. 3C and 3D depict operation 304. Inoperation 304, an image sensor die 104 is coupled to the substrate 102,and bond wires 122 are connected to the image sensor die 104 and thesubstrate 102. FIG. 3C illustrates a side view of the image sensor die104 and the substrate 102. FIG. 3D illustrates a top view of the imagesensor die 104 and the substrate 102. In operation 304, the image sensordie 104 is coupled to the substrate 102 using a die attach film, and thebond wires 122 are connected to the contact terminals 117 on the imagesensor die 104 and the substrate 102.

FIGS. 3E and 3F depict operation 306. In operation 306, pillar members125 are formed on a mount area 123 of the image sensor die 104. FIG. 3Eillustrates a side view of the image sensor package. FIG. 3F illustratesa top view of the image sensor package. In operation 306, a dispenser150 dispenses a liquid epoxy resin on the corner portions of the mountarea 123 to create the pillar members 125.

FIG. 3H and 3I depict operation 308. In operation 308, UV light 152 isapplied to the liquid epoxy resin to cure the liquid epoxy resin toharden the pillar members 125. FIG. 3H illustrates a side view of theimage sensor package. FIG. 3I illustrates a top view of the image sensorpackage.

FIGS. 3J and 3K depict operation 310. In operation 310, the dispenser150 dispenses the bonding material 124 on the mount area 123 of theimage sensor die 104. FIG. 3J illustrates a side view of the imagesensor package. FIG. 3K illustrates a top view of the image sensorpackage.

FIGS. 3L and 3M depict operation 312. In operation 312, the transparentmember 106 is placed on the bonding material 124 and the pillar members,and UV light 152 is applied to the bonding material 124 to couple thetransparent member 106 to the image sensor die 104. FIG. 3N depictsoperation 314. In operation 314, the dispenser 150 dispenses anencapsulation material 130 to the substrate 102, and conductivecomponents 120 coupled to the substrate 102.

FIG. 4 illustrate a system 450 for defining a gap height 405 within animage sensor package 400 according to an aspect. In some examples, theimage sensor package 400 includes a complementarymetal-oxide-semiconductor (CMOS) image sensor (CIS) package. The imagesensor package 400 may include any of the features described withrespect to the previous figures. The image sensor package 400 includes asubstrate 402, an image sensor die 404 coupled to the substrate 202, anda transparent member 406 coupled to the image sensor die 404 such thatan air gap 403 (e.g., empty space) exists between an active region 408of the image sensor die 404 and the transparent member 406.

The substrate 402 includes a first surface 412 and a second surface 414.The first surface 412 of the substrate 402 is disposed in a plane A4. Insome examples, the second surface 414 is disposed in parallel with thefirst surface 412. A direction A1 is aligned perpendicular to the planeA4, and a direction A2 is perpendicular to the direction A1. A directionA3 is aligned parallel to the plane A4 and is orthogonal to directionsA1 and A2. As shown in FIG. 4 , the direction A3 is depicted into thepage (shown as a dot). The directions A1, A2, and A3, and plane A4, areused throughout several of the various views of the implementationsdescribed throughout the figures for simplicity. The image sensor die404 includes a first surface 416 and a second surface 418. The firstsurface 416 defines an active region 408 of the image sensor die 404.The transparent member 406 includes a first surface 426 and a secondsurface 428.

The gap height 405 is the height of the air gap 403. The air gap 403 maybe empty space (e.g., devoid of components). The gap height 405 is thedistance between the active region 408 of the image sensor die 404 andthe transparent member 406 in the direction A1. In some examples, thegap height 405 is the distance between the second surface 428 of thetransparent member 406 and the first surface 416 of the image sensor die404 in the direction A1. According to the techniques described herein,the gap height 405 can be defined in a relatively precise manner inorder to meet a desired designed specification. Also, in some examples,the gap height 405 can be increased to provide a relatively larger airgap 403, which may be beneficial for some applications.

In order to couple the transparent member 406 to the image sensor die401, a bonding material 424 is dispensed on a mount area of the imagesensor die 404. In some examples, the bonding material 424 includes aliquid epoxy resin that is dispensed on the mount area of the imagesensor die 404. Then, the transparent member 406 is coupled to a bondhead 401. The bond head 401 may be a movable device that uses vacuumsuction to couple the transparent member 406 to the bond head 401. Forexample, activation of the vacuum suction on the bond head 401 causesthe transparent member 406 to contact and remain attached to the bondhead 401. Then, the bond head 401 is moved to a programmable position484 to place the transparent member 406 in contact with the bondingmaterial 424. The programmable position 484 defines the gap height 405between the active region 408 and the transparent member 406. Forexample, the programmable position 484 may define the location and theheight of the bond head 401, which defines the gap height 405. After thebond head 401 is moved to the programmable position 484, the bondingmaterial 424 is curved to form a solid material. In some examples, thebonding material 424 is curved using UV light.

The bond head 401 may be communicatively coupled to a controller 480.The controller 480 may include one or more processors (e.g.,microprocessors) that execute instructions to control the movement ofthe bond head 401. In some examples, the bond head 401 and thecontroller 480 are included as part of a single integrated device. Insome examples, the controller 480 is a device separate from the bondhead 401, where the controller 480 is connected to the bond head 401 viaone or more communication lines (or connected via wirelesscommunication). The programmable position 484 (to which the bond head401 moves to) may be reprogrammed by a user. For example, theprogrammable position 484 may be reprogrammed to increase the gap height405 between the active region 408 of the image sensor die 404 and thetransparent member 406. In some examples, the programmable position 484may be programmed such that the gap height 405 is relatively large. Insome examples, the gap height 405 is equal to or greater than 0.5millimeters (mm). In some examples, the gap height 405 is equal to orgreater 0.7 mm. In some examples, the gap height 405 is equal to orgreater 0.1 mm. In some examples, when the gap height 405 is relativelylarge, the bonding material 424 may be a viscosity greater than athreshold level. In some examples, the threshold level may be greaterthan 50,000 centipoise (cps).

The substrate 402 includes a printed circuit board (PCB) substrate. Insome examples, the substrate 402 includes a dielectric material. In someexamples, the substrate 402 includes a single layer of PCB basematerial. In some examples, the substrate 402 includes multiple layersof PCB base material. The image sensor die 404 may include acomplementary metal-oxide semiconductor (CMOS) image sensor. In someexamples, the first surface 416 (and/or the second surface 418) isparallel to the first surface 412 (and/or the second surface 414). Theimage sensor die 404 defines the active region 408 on the first surface416 of the image sensor die 404. The active region 408 may have orcorrespond with, an array of pixel elements configured to convertelectromagnetic radiation (e.g., light) to electrical signals.

The image sensor die 404 is coupled to the substrate 402. For example,the second surface 418 of the image sensor die 404 may be coupled tofirst surface 412 of the substrate 402 using one or more bondingmaterials (e.g., an adhesive layer, die attach film, polymer-basedmaterial, an epoxy resin, etc.) in order to physically couple the imagesensor die 404 to the substrate 402. In some examples, the bond wires422 are connected to the image sensor die 404 and the substrate 402 inorder to communicatively couple the image sensor die 404 to thesubstrate 402. The bond wires 422 may include conductive (e.g., metal)wires such as aluminum, copper, or gold, or any combination thereof, forexample. In some examples, the image sensor die 404 is coupled to thesubstrate 402 in a flip-chip configuration. In some examples, the imagesensor die 404 is coupled to the substrate 402 by surface mounttechnology (SMT) (e.g., interconnection by solder joint). In someexamples, the image sensor die 404 is coupled to the first surface 412of the substrate 202 using one or more bump members (e.g., copperpillars with solder, gold plated bumps, solder bumps, and/or gold studbumps, etc.). In some examples, an under-fill material is disposedwithin the gap between the image sensor die 204 and the substrate 202,where the under-fill material encapsulates the bump members.

The transparent member 406 is coupled to the image sensor die 404 suchthat the transparent member 406 is positioned over (and spaced apartfrom) the active region 408 on the first surface 416 of the image sensordie 404 in the direction A1. In some examples, the first surface 426(and/or the second surface 428) is parallel to the first surface 416(and/or the second surface 418). The transparent member 406 includes anoptically transparent material that allows electromagnetic radiation(e.g., light (e.g., visible light)) to pass through (e.g., pass throughthe entirety of the material). In some examples, the transparent member406 includes a glass material.

FIG. 5 illustrates a system 550 for defining a gap height 505 within animage sensor package 500 according to an aspect. In some examples, theimage sensor package 500 includes a complementarymetal-oxide-semiconductor (CMOS) image sensor (CIS) package. The imagesensor package 500 may include any of the features described withrespect to the previous figures. The image sensor package 500 includes asubstrate 502, an image sensor die 504 coupled to the substrate 202, anda transparent member 506 coupled to the image sensor die 504 such thatan air gap 503 (e.g., an empty space) exists between an active region508 of the image sensor die 504 and the transparent member 506.

The substrate 502 includes a first surface 512 and a second surface 514.The first surface 512 of the substrate 502 is disposed in a plane A4. Insome examples, the second surface 514 is disposed in parallel with thefirst surface 512. A direction A1 is aligned perpendicular to the planeA4, and a direction A2 is perpendicular to the direction A1. A directionA3 is aligned parallel to the plane A4 and is orthogonal to directionsA1 and A2. As shown in FIG. 5 , the direction A3 is depicted into thepage (shown as a dot). The directions A1, A2, and A3, and plane A4, areused throughout several of the various views of the implementationsdescribed throughout the figures for simplicity. The image sensor die504 includes a first surface 516 and a second surface 518. The firstsurface 516 defines an active region 508 of the image sensor die 504.The transparent member 506 includes a first surface 526 and a secondsurface 528.

The gap height 505 is the height of the air gap 503. The air gap 503 maybe empty space (e.g., devoid of components). The gap height 505 is thedistance between the active region 508 of the image sensor die 504 andthe transparent member 506 in the direction A1. In some examples, thegap height 505 is the distance between the second surface 528 of thetransparent member 506 and the first surface 516 of the image sensor die504 in the direction A1. According to the techniques described herein,the gap height 505 can be defined in a relatively precise manner inorder to meet a desired designed specification. Also, in some examples,the gap height 505 can be increased to provide a relatively larger airgap 503, which may be beneficial for some applications.

In order to couple the transparent member 506 to the image sensor die501, a bonding material 524 is dispensed on a mount area of the imagesensor die 504. In some examples, the bonding material 524 includes aliquid epoxy resin that is dispensed on the mount area of the imagesensor die 504. Then, the transparent member 506 is coupled to a bondhead 501. The bond head 501 may be a movable device that uses vacuumsuction to couple the transparent member 506 to the bond head 501. Forexample, activation of the vacuum suction on the bond head 501 causesthe transparent member 506 to contact and remain attached to the bondhead 501. Then, the bond head 501 is moved to a programmable position toplace the transparent member 506 in contact with the bonding material524. The programmable position defines the gap height 505 between theactive region 508 and the transparent member 506. For example, theprogrammable position may define the location and the height of the bondhead 501, which defines the gap height 505. After the bond head 501 ismoved to the programmable position, the bonding material 524 is curvedto form a solid material. In some examples, the bonding material 524 iscurved using UV light 552.

The substrate 502 includes a printed circuit board (PCB) substrate. Insome examples, the substrate 502 includes a dielectric material. In someexamples, the substrate 502 includes a single layer of PCB basematerial. In some examples, the substrate 502 includes multiple layersof PCB base material. The image sensor die 504 may include acomplementary metal-oxide semiconductor (CMOS) image sensor. In someexamples, the first surface 516 (and/or the second surface 518) isparallel to the first surface 512 (and/or the second surface 514). Theimage sensor die 504 defines the active region 508 on the first surface516 of the image sensor die 504. The active region 508 may have orcorrespond with, an array of pixel elements configured to convertelectromagnetic radiation (e.g., light) to electrical signals.

The image sensor die 504 is coupled to the substrate 502. For example,the second surface 518 of the image sensor die 504 may be coupled tofirst surface 512 of the substrate 502 using one or more bondingmaterials (e.g., an adhesive layer, die attach film, polymer-basedmaterial, an epoxy resin, etc.) in order to physically couple the imagesensor die 504 to the substrate 502. In some examples, the bond wires522 are connected to the image sensor die 504 and the substrate 502 inorder to communicatively couple the image sensor die 504 to thesubstrate 502. The bond wires 522 may include conductive (e.g., metal)wires such as aluminum, copper, or gold, or any combination thereof, forexample. In some examples, the image sensor die 504 is coupled to thesubstrate 502 in a flip-chip configuration. In some examples, the imagesensor die 504 is coupled to the substrate 502 by surface mounttechnology (SMT) (e.g., interconnection by solder joint). In someexamples, the image sensor die 504 is coupled to the first surface 512of the substrate 202 using one or more bump members (e.g., copperpillars with solder, gold plated bumps, solder bumps, and/or gold studbumps, etc.). In some examples, an under-fill material is disposedwithin the gap between the image sensor die 404 and the substrate 202,where the under-fill material encapsulates the bump members.

The transparent member 506 is coupled to the image sensor die 504 suchthat the transparent member 506 is positioned over (and spaced apartfrom) the active region 508 on the first surface 516 of the image sensordie 504 in the direction A1. In some examples, the first surface 526(and/or the second surface 528) is parallel to the first surface 516(and/or the second surface 518). The transparent member 506 includes anoptically transparent material that allows electromagnetic radiation(e.g., light (e.g., visible light)) to pass through (e.g., pass throughthe entirety of the material). In some examples, the transparent member406 includes a glass material.

The image sensor package 500 may include one or more conductivecomponents 520 coupled to the second surface 514 of the substrate 502.In some examples, the conductive components 520 are surface-mountpackaging elements. In some examples, the conductive components 520include solder balls. The conductive components 520 are components usedto connect to an external device (e.g., a ball grid array (BGA) device).However, the conductive components 520 may include other types ofsurface-mount packaging elements.

FIGS. 6A through 6F depict a flowchart depicting example fabricationoperations for manufacturing an image sensor package according to anaspect. Although the flowchart is described with reference to the imagesensor package 400 of FIG. 4 , the flowchart may be applicable to any ofthe sensor packaging packages discussed herein. Although the flowchartof FIGS. 6A through 6F illustrate operations in sequential order, itwill be appreciated that this is merely an example, and that additionalor alternative operations may be included. Further, operations of FIGS.6A through 6F and related operations may be executed in a differentorder than that shown, or in a parallel or overlapping fashion.

In FIG. 6A, operation 602 includes providing an image sensor die 404coupled to a substrate 402. The image sensor die 404 includes an activeregion 408. Bond wires 422 are coupled to the image sensor die 404 andthe substrate 402.

In FIG. 6B, operation 604 includes dispensing bonding material 424 onthe image sensor die 404. In FIG. 6C, operation 606 includes moving thebond head 401 coupled to the transparent member 406 to place thetransparent member 406 in contact with the bonding material 424. Forexample, the bond head 401 may be coupled to the transparent member 406,and the bond head 401 is moved to a programmable position in order todefine the gap height. In some examples, vacuum suction is activated onthe bond head 401 in order to couple the bond head 401 with thetransparent member 406. In FIG. 6C, operation 608 includes applying UVlight 452 to the bonding material 424 to cure the bonding material 424.For example, the bonding material 424 is cured with the UV light 452while the bond head 401 is still coupled to the transparent member 406.In this manner, the distance between the image sensor die 404 and thetransparent member 406 is remained fixed by the bond head 401 while therelatively soft bonding material 424 is hardened by the UV light 452,thereby providing a relatively precise gap height. In some examples, thebonding material 424 includes a liquid epoxy resin, and the liquid epoxyresin is dispensed on the image sensor die 404. Then, in operation 608,UV light 452 is applied to cure the liquid epoxy resin to form a solidbonding material.

In FIG. 6E, operation 610 includes decoupling the bond head 401 from thetransparent member 406 and moving the bond head 401 away from thetransparent member 406. In some examples, vacuum suction is deactivatedon the bond head 401 to release the transparent member 406 from the bondhead 401. In FIG. 6F, operation 612 includes dispending a moldingmaterial 430 on the substrate 402 to encapsulate the bond wires 422.Operation 612 includes coupling conductive members 420 to the substrate402. The conductive members 420 are configured to be connected to anexternal device.

FIG. 7 depicts a flowchart 700 depicting example fabrication operationsfor manufacturing an image sensor package according to an aspect.Although the flowchart 700 is described with reference to the imagesensor package 100 of FIGS. 1A through 1C, the flowchart may beapplicable to any of the sensor packaging packages discussed herein.Although the flowchart 700 of FIG. 7 illustrates operations insequential order, it will be appreciated that this is merely an example,and that additional or alternative operations may be included. Further,operations of FIG. 7 and related operations may be executed in adifferent order than that shown, or in a parallel or overlappingfashion.

Operation 702 includes coupling an image sensor die 104 to a substrate102. Operation 704 includes forming a plurality of pillar members 125 onthe image sensor die 104. Operation 706 includes dispensing a bondingmaterial 124 on the image sensor die 104. Operation 708 includescontacting a transparent member 106 with the bonding material 124 suchthat a height of the pillar members 125 defines a gap height 105 betweenan active region 108 of the image sensor die 104 and the transparentmember 106. Operation 710 includes curing the bonding material 124 tocouple the transparent member 106 to the image sensor die 104.

FIG. 8 depicts a flowchart 800 depicting example fabrication operationsfor manufacturing an image sensor package according to an aspect.Although the flowchart 800 is described with reference to the imagesensor package 100 of FIGS. 1A through 1C, the flowchart may beapplicable to any of the sensor packaging packages discussed herein.Although the flowchart 800 of FIG. 8 illustrates operations insequential order, it will be appreciated that this is merely an example,and that additional or alternative operations may be included. Further,operations of FIG. 8 and related operations may be executed in adifferent order than that shown, or in a parallel or overlappingfashion.

Operation 802 includes coupling an image sensor die 104 to a substrate102. Operation 804 includes coupling bond wires 122 to the image sensordie 104 and to the substrate 102. Operation 806 includes forming aplurality of pillar members 125 on a mount area 123 of the image sensordie 102, where the mount area 123 is disposed outside an active region108 of the image sensor die 104. Operation 808 includes dispensing abonding material 124 on the mount area 123 of the image sensor die 104.Operation 810 includes contacting a transparent member 106 with thebonding material 124 such that a height of the plurality of pillarmembers 125 defines a gap height 105 between the active region 108 ofthe image sensor die 104 and the transparent member 106. Operation 812includes curing the bonding material 124 to couple the transparentmember 106 to the image sensor die 104.

FIG. 9 depicts a flowchart 900 depicting example fabrication operationsfor manufacturing an image sensor package according to an aspect.Although the flowchart 900 is described with reference to the imagesensor package 400 of FIG. 4 , the flowchart may be applicable to any ofthe sensor packaging packages discussed herein. Although the flowchart900 of FIG. 9 illustrates operations in sequential order, it will beappreciated that this is merely an example, and that additional oralternative operations may be included. Further, operations of FIG. 9and related operations may be executed in a different order than thatshown, or in a parallel or overlapping fashion.

Operation 902 includes dispensing a bonding material 424 on a mount areaof an image sensor die 404, where the image sensor die 404 is coupled toa substrate 402. Operation 904 includes coupling a transparent member406 to a bond head 401. Operation 906 includes moving the bond head 401to a programmable position 484 to place the transparent member 406 incontact with the bonding material 424, where the programmable position484 defines a gap height 405 between an active region 408 of the imagesensor die 404 and the transparent member 406. Operation 908 includescuring the bonding material 424 to couple the transparent member 406 tothe image sensor die 404 while the bond head 401 is coupled to thetransparent member 406. Operation 910 includes releasing the bond head401 from the transparent member 406.

It will be understood that, in the foregoing description, when anelement is referred to as being connected to, electrically connected to,coupled to, or electrically coupled to another element, it may bedirectly connected or coupled to the other element, or one or moreintervening elements may be present. In contrast, when an element isreferred to as being directly connected to or directly coupled toanother element, there are no intervening elements. Although the termsdirectly connected to, or directly coupled to may not be used throughoutthe detailed description, elements that are shown as being directlyconnected or directly coupled can be referred to as such. The claims ofthe application, if any, may be amended to recite exemplaryrelationships described in the specification or shown in the figures.Implementations of the various techniques described herein may beimplemented in (e.g., included in) digital electronic circuitry, or incomputer hardware, firmware, software, or in combinations of them.Portions of methods also may be performed by, and an apparatus may beimplemented as, special purpose logic circuitry, e.g., an FPGA (fieldprogrammable gate array) or an ASIC (application specific integratedcircuit).

Some implementations may be implemented using various semiconductorprocessing and/or packaging techniques. Some implementations may beimplemented using various types of semiconductor processing techniquesassociated with semiconductor substrates including, but not limited to,for example, Silicon (Si), Gallium Arsenide (GaAs), Gallium Nitride(GaN), Silicon Carbide (SiC) and/or so forth.

While certain features of the described implementations have beenillustrated as described herein, many modifications, substitutions,changes and equivalents will now occur to those skilled in the art. Itis, therefore, to be understood that the appended claims are intended tocover all such modifications and changes as fall within the scope of theembodiments. It should be understood that they have been presented byway of example only, not limitation, and various changes in form anddetails may be made. Any portion of the apparatus and/or methodsdescribed herein may be combined in any combination, except mutuallyexclusive combinations. The embodiments described herein can includevarious combinations and/or sub-combinations of the functions,components and/or features of the different embodiments described.

What is claimed is:
 1. An image sensor package comprising: a substrate;an image sensor die coupled to the substrate; a light transmittingmember; a plurality of pillar members disposed between and contactingthe image sensor die and the light transmitting member, a height of theplurality of pillar members defining a gap height between an activeregion of the image sensor die and the light transmitting member; and abonding material that couples the light transmitting member to the imagesensor die, the bonding material contacting a side of a pillar member,of the plurality of pillar members, that extends between a first endcontacting the light transmitting member and a second end contacting theimage sensor die.
 2. The image sensor package of claim 1, wherein thebonding material is disposed on a perimeter portion of a mount area ofthe image sensor die.
 3. The image sensor package of claim 2, whereineach of the plurality of pillar members is located on a separate cornerportion of the mount area of the image sensor die.
 4. The image sensorpackage of claim 1, further comprising: one or more bond wires coupledto the image sensor die and the substrate.
 5. The image sensor packageof claim 1, wherein the image sensor die includes a plurality of contactterminals, the plurality of pillar members located between the activeregion and the plurality of pillar members.
 6. The image sensor packageof claim 1, wherein the pillar member includes an L-shape.
 7. The imagesensor package of claim 1, wherein the substrate includes conductivetraces.
 8. The image sensor package of claim 1, further comprising: anencapsulation material having a portion that contacts the bondingmaterial.
 9. The image sensor package of claim 1, wherein the pillarmember includes a first linear portion and a second linear portion, thesecond linear portion extending from the first linear portion, thesecond linear portion being disposed at a non-zero angle with respect tothe first linear portion.
 10. An image sensor package comprising: asubstrate; an image sensor die coupled to the substrate; a lighttransmitting member; a plurality of pillar members disposed between andcontacting the image sensor die and the light transmitting member; abonding material that couples the light transmitting member to the imagesensor die, the bonding material contacting a side of a pillar member,of the plurality of pillar members, that extends between a first endcontacting the light transmitting member and a second end contacting theimage sensor die; a bond wire coupled to the substrate and the imagesensor die; and an encapsulation material that encapsulates the bondwire.
 11. The image sensor package of claim 10, wherein a height of theplurality of pillar members defining a gap height between an activeregion of the image sensor die and the light transmitting member. 12.The image sensor package of claim 10, wherein the bonding material isdisposed on a perimeter portion of a mount area of the image sensor die,each of the plurality of pillar members located on a separate cornerportion of the mount area of the image sensor die.
 13. The image sensorpackage of claim 10, wherein the image sensor die includes a pluralityof contact terminals, the plurality of pillar members located between anactive region of the image sensor die and the plurality of pillarmembers.
 14. The image sensor package of claim 10, wherein the pillarmember includes a first linear portion extending a first direction and asecond linear portion extending in a second direction, a height of thepillar member extending in a third direction, wherein the firstdirection, the second direction, and the third direction are orthogonalto each other.
 15. The image sensor package of claim 10, wherein thepillar member includes an L-shape.
 16. The image sensor package of claim10, wherein the substrate includes conductive traces.
 17. The imagesensor package of claim 10, wherein the encapsulation material includesa portion that contacts the bonding material.
 18. An image sensorpackage comprising: a substrate; an image sensor die coupled to thesubstrate, the image sensor die including an active region and aplurality of contact terminals; a light transmitting member; a pluralityof pillar members disposed between and contacting the image sensor dieand the light transmitting member, the plurality of pillar members beinglocated between the active region and the plurality of contactterminals; and a bonding material that couples the light transmittingmember to the image sensor die, the bonding material contacting a sideof a pillar member, of the plurality of pillar members, that extendsbetween a first end contacting the light transmitting member and asecond end contacting the image sensor die.
 19. The image sensor packageof claim 18, further comprising: a bond wire coupled to the substrateand a contact terminal of the plurality of contact terminals; anencapsulation material that encapsulates the bond wire; and a pluralityof conductive members coupled to the substrate.
 20. The image sensorpackage of claim 18, wherein the bonding material is disposed on aperimeter portion of a mount area of the image sensor die, each of theplurality of pillar members located on a separate corner portion of themount area of the image sensor die, the pillar member including a firstlinear portion and a second linear portion, the second linear portionextending from the first linear portion, the second linear portion beingdisposed at a non-zero angle with respect to the first linear portion.